What are AMOLED or Emissive Displays?

About Emissive Displays

Active-Matrix Organic Light-Emitting Diode (AMOLED) is a relatively new display technology for wearable devices, mobile phones, televisions, and everything in between. Currently used on the Apple Watch and several top Android Smartphones like the LG Flex, Nexus and Samsung Galaxy S series, the market for AMOLED displays is expected to reach a level of $28.3 billion by 2020, according to research firm DisplaySearch.

OLED (Organic Light-Emitting Diode) refers to the thin film of organic material on top of the display. When electrical current is applied to this film, it gives off light, just like a regular LED – except it’s only a few nanometers thick. Learn more about OLEDs on Wikipedia.

AM (Active Matrix) refers to how the display is addressed. Each pixel has an active element (a thin-film transistor, or TFT) that actively provides current to the OLED, maintaining that pixel’s brightness while the other pixels are being addressed. Without the active matrix, OLED displays are small and low-resolution, used for applications like mobile phone sub-displays.

AMOLED versus AMLCD displays

AMOLED displays are a next-generation technology; they offer both higher performance, and lower potential cost than today’s high quality AMLCDs.

Liquid crystal and polarizers: these layers work together to block the light or let it through

TFT backplane: the circuits in the TFT backplane control the liquid crystal, twisting it to block the light or allow it to pass

Color filter: filters the (white) light from the backlight to make the red, green and blue subpixels

Because of the nature of AMLCD displays, they have the following problems:

Most of the backlight’s light is lost in the LCD layers; only about 5% of the light makes it through the front of the display

The backlight must be on even during dim images, wasting a lot of power.

The liquid crystal layer can’t block all the light, so some light leaks through, making the blacks “gray”

Because the light comes from the backlight, and has to pass through several layers, the viewing angle can be poor

The colors filters are inefficient, so to save power they are often thin, leading to washed-out colors.

How AMOLED Displays Work

AMOLED displays are inherently simpler and have only two main layers:

An OLED (organic light-emitting diode) layer that emits light.

A backplane made of TFT (thin-film transistor) circuits that provide current to the OLEDs, thereby controlling their brightness.

There’s usually a polarizer on top, which cuts reflected light. And that’s it! The simpler structure will lead to lower cost than LCDs, in addition to being thinner and lighter.

AMOLEDs also have other advantages:

Lower Power: Only those pixels that are lit up consume power; dim screens (such as white text on a black background) consume almost no power, and video (where the pixels are only about 30% on) consumes much less power than LCD.

Higher Contrast: When a pixel is off, no light comes out all. This high contrast (over 100,000:1) gives stunning image quality

Better Viewing Angle: Because the light comes from the OLEDs on top of the display, the viewing angle is a true 180 degrees with no color shift

Richer Colors: The colors of the OLEDs are rich and deep, so the display looks much more vibrant than LCD.

Of course, AMOLEDs aren’t perfect yet. The materials used to make the OLED and the backplane aren’t completely uniform or stable. IGNIS technology was created to address these problems. Our solutions give highly uniform, long-lasting AMOLED displays even with non-uniform, unstable materials.

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